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Please use this identifier to cite or link to this item: https://oldena.lpnu.ua/handle/ntb/46148
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dc.contributor.authorРижа, І.
dc.contributor.authorГайдучок, О.
dc.contributor.authorRyzha, I.
dc.contributor.authorGaiduchok, O.
dc.date.accessioned2020-02-27T09:45:18Z-
dc.date.available2020-02-27T09:45:18Z-
dc.date.created2019-02-26
dc.date.issued2019-02-26
dc.identifier.citationRyzha I. Mathematical model for carbon monoxide oxidation: influence of diffusion effects / I. Ryzha, O. Gaiduchok // Mathematical Modeling and Computing. — Lviv : Lviv Politechnic Publishing House, 2019. — Vol 6. — No 1. — P. 129–136.
dc.identifier.urihttps://ena.lpnu.ua/handle/ntb/46148-
dc.description.abstractДосліджено двовимірну математичну модель окиснення монооксиду вуглецю на поверхні платинового каталізатора згідно з механізмом Ленгмюра–Гіншелвуда, яка враховує вплив дифузійних ефектів на перебіг реакційно-дифузійних процесів. Встановлено, що адсорбовані атоми кисню можна вважати нерухомими, а структурні зміни поверхні каталізатора істотно впливають на характер коливного режиму реакції.
dc.description.abstractA two-dimensional mathematical model for carbon monoxide oxidation on the platinum catalyst surface is investigated according to the Langmuir–Hinshelwood mechanism. This model takes into account the influence of diffusion effects on the course of reaction-diffusion processes. It is established that the diffusion of adsorbed oxygen atoms can be neglected, and the structural changes of the catalyst surface have a significant influence on the character of oscillatory mode of reaction.
dc.format.extent129-136
dc.language.isoen
dc.publisherLviv Politechnic Publishing House
dc.relation.ispartofMathematical Modeling and Computing, 1 (6), 2019
dc.subjectкаталітична реакція окиснення
dc.subjectреакційно-дифузійна модель
dc.subjectматематичне моделювання реакційно-дифузійних процесів
dc.subjectreaction of catalytic oxidation
dc.subjectreaction-diffusion model
dc.subjectmathematical modeling of reaction-diffusion processes
dc.titleMathematical model for carbon monoxide oxidation: influence of diffusion effects
dc.title.alternativeМатематична модель оксидації чадного газу: вплив дифузійних ефектів
dc.typeArticle
dc.rights.holderCMM IAPMM NAS
dc.rights.holder© 2019 Lviv Polytechnic National University
dc.contributor.affiliationНаціональний університет “Львівська політехніка”
dc.contributor.affiliationLviv Polytechnic National University
dc.format.pages8
dc.identifier.citationenRyzha I. Mathematical model for carbon monoxide oxidation: influence of diffusion effects / I. Ryzha, O. Gaiduchok // Mathematical Modeling and Computing. — Lviv : Lviv Politechnic Publishing House, 2019. — Vol 6. — No 1. — P. 129–136.
dc.relation.references1. KrischerK., EiswirthM., ErtlG. Oscillatory CO oxidation on Pt(110): Modeling of temporal selforganization. J. Chem. Phys. 96 (12), 9161–9172 (1992).
dc.relation.references2. ZiffR.M., GulariE., BarshadY. Kinetic phase transitions in an irreversible surface-reaction model. Phys. Rev. Lett. 56 (24), 2553–2556 (1986).
dc.relation.references3. B¨arM., Z¨ulickeC., EiswirthM., ErtlG. Theoretical modeling of spatiotemporal self-organization in a surface catalyzed reaction exhibiting bistable kinetics. J. Chem. Phys. 96 (11), 8595–8604 (1992).
dc.relation.references4. Bzovska I. S., Mryglod I.M. Surface Patterns in Catalytic Carbon Monoxide Oxidation Reaction. Ukr. J. Phys. 61 (2), 134–142 (2016).
dc.relation.references5. Qiao L., LiX., Kevrekidis I.G., PuncktC., RotermundH.H. Enhancement of surface activity in CO oxidation on Pt(110) through spatiotemporal laser actuation. Phys. Rev. E. 77, 036214 (2008).
dc.relation.references6. CisternasY., Holmes P., Kevrekidis I.G., LiX. CO oxidation on thin Pt crystals: Temperature slaving and the derivation of lumped models. J. Chem. Phys. 118 (7), 3312–3328 (2003).
dc.relation.references7. B¨arM., GottschalkN., EiswirthM., ErtlG. Spiral waves in a surfacereaction: model calculations. J. Chem. Phys. 100 (2), 1202–1214 (1994).
dc.relation.references8. PavlenkoN. CO-activator model for reconstructing Pt(100) surfaces: Local microstructures and chemical turbulence. Phys. Rev. E. 77, 026203–1–10 (2008).
dc.relation.references9. KostrobijP., Ryzha I., MarkovychB. Mathematical model of carbon monoxide oxidation: influence of the catalyst surface structure. Mathematical Modeling and Computing. 5 (2), 158–168 (2018).
dc.relation.references10. Langmuir I. The mechanism of the catalytic action of platinum in the reactions 2CO + O2 = 2CO2 and 2H2 + O2 = 2H2O. Trans. Faraday Soc. 17, 621–654 (1922).
dc.relation.references11. ImbihlR., ErtlG. Oscillatory Kinetics in Heterogeneous Catalysis. Chem. Rev. 95 (3), 697–733 (1995).
dc.relation.references12. GritschT., CoulmanD., BehmR. J., ErtlG. Mechanism of the CO-induced (1×2)−(1×1) structural transformation of Pt(110). Phys. Rev. Lett. 63 (10), 1086–1089 (1989).
dc.relation.references13. Ladas S., ImbihlR., ErtlG. Microfacetting of a Pt(110) surface during catalytic CO oxidation. Surf. Science. 197 (1–2), 153–182 (1988).
dc.relation.references14. Ladas S., ImbihlR., ErtlG. Kinetic oscillations and facetting during the catalytic CO oxidation on Pt(110). Surf. Science. 198 (1–2), 42–68 (1988).
dc.relation.references15. von OertzenA., RotermundH.H., NettesheimS. Diffusion of carbon monoxide and oxygen on Pt(110): experiments performed with the PEEM. Surf. Science. 311 (3), 322–330 (1994).
dc.relation.references16. van KampenN.G. Stohasticheskie processy v fizike i himii. Vysshaja shkola, Moskva (1990), (in Russian).
dc.relation.references17. Bzovska I. S., Mryglod I.M. Chemical oscillations in catalytic CO oxidation reaction. Condens. Matter Phys. 13 (3), 34801:1–5 (2010).
dc.relation.references18. ConnorsK.A. Chemical Kinetics: The Study of Reaction Rates in Solution. VCH Publishers, New York (1990).
dc.relation.references19. KuchlingH. Physik Nachschlageb¨ucher f¨ur Grundlagenf¨acher. VEB Fachbuchverlag, Leipzig (1973), (in German).
dc.relation.references20. PatchettA. J., Meissen F., EngelW., BradshawA.M., ImbihlR. The anatomy of reaction diffusion fronts in the catalytic oxidation of carbon monoxide on platinum (110). Surf. Science. 454 (1), 341–346 (2000).
dc.relation.references21. KostrobijP., Ryzha I. Two-dimensional mathematical model for carbon monoxide oxidation process on the platinum catalyst surface. Chem. Chem. Technol. 12 (4), 451–455 (2018).
dc.relation.referencesen1. KrischerK., EiswirthM., ErtlG. Oscillatory CO oxidation on Pt(110): Modeling of temporal selforganization. J. Chem. Phys. 96 (12), 9161–9172 (1992).
dc.relation.referencesen2. ZiffR.M., GulariE., BarshadY. Kinetic phase transitions in an irreversible surface-reaction model. Phys. Rev. Lett. 56 (24), 2553–2556 (1986).
dc.relation.referencesen3. B¨arM., Z¨ulickeC., EiswirthM., ErtlG. Theoretical modeling of spatiotemporal self-organization in a surface catalyzed reaction exhibiting bistable kinetics. J. Chem. Phys. 96 (11), 8595–8604 (1992).
dc.relation.referencesen4. Bzovska I. S., Mryglod I.M. Surface Patterns in Catalytic Carbon Monoxide Oxidation Reaction. Ukr. J. Phys. 61 (2), 134–142 (2016).
dc.relation.referencesen5. Qiao L., LiX., Kevrekidis I.G., PuncktC., RotermundH.H. Enhancement of surface activity in CO oxidation on Pt(110) through spatiotemporal laser actuation. Phys. Rev. E. 77, 036214 (2008).
dc.relation.referencesen6. CisternasY., Holmes P., Kevrekidis I.G., LiX. CO oxidation on thin Pt crystals: Temperature slaving and the derivation of lumped models. J. Chem. Phys. 118 (7), 3312–3328 (2003).
dc.relation.referencesen7. B¨arM., GottschalkN., EiswirthM., ErtlG. Spiral waves in a surfacereaction: model calculations. J. Chem. Phys. 100 (2), 1202–1214 (1994).
dc.relation.referencesen8. PavlenkoN. CO-activator model for reconstructing Pt(100) surfaces: Local microstructures and chemical turbulence. Phys. Rev. E. 77, 026203–1–10 (2008).
dc.relation.referencesen9. KostrobijP., Ryzha I., MarkovychB. Mathematical model of carbon monoxide oxidation: influence of the catalyst surface structure. Mathematical Modeling and Computing. 5 (2), 158–168 (2018).
dc.relation.referencesen10. Langmuir I. The mechanism of the catalytic action of platinum in the reactions 2CO + O2 = 2CO2 and 2H2 + O2 = 2H2O. Trans. Faraday Soc. 17, 621–654 (1922).
dc.relation.referencesen11. ImbihlR., ErtlG. Oscillatory Kinetics in Heterogeneous Catalysis. Chem. Rev. 95 (3), 697–733 (1995).
dc.relation.referencesen12. GritschT., CoulmanD., BehmR. J., ErtlG. Mechanism of the CO-induced (1×2)−(1×1) structural transformation of Pt(110). Phys. Rev. Lett. 63 (10), 1086–1089 (1989).
dc.relation.referencesen13. Ladas S., ImbihlR., ErtlG. Microfacetting of a Pt(110) surface during catalytic CO oxidation. Surf. Science. 197 (1–2), 153–182 (1988).
dc.relation.referencesen14. Ladas S., ImbihlR., ErtlG. Kinetic oscillations and facetting during the catalytic CO oxidation on Pt(110). Surf. Science. 198 (1–2), 42–68 (1988).
dc.relation.referencesen15. von OertzenA., RotermundH.H., NettesheimS. Diffusion of carbon monoxide and oxygen on Pt(110): experiments performed with the PEEM. Surf. Science. 311 (3), 322–330 (1994).
dc.relation.referencesen16. van KampenN.G. Stohasticheskie processy v fizike i himii. Vysshaja shkola, Moskva (1990), (in Russian).
dc.relation.referencesen17. Bzovska I. S., Mryglod I.M. Chemical oscillations in catalytic CO oxidation reaction. Condens. Matter Phys. 13 (3), 34801:1–5 (2010).
dc.relation.referencesen18. ConnorsK.A. Chemical Kinetics: The Study of Reaction Rates in Solution. VCH Publishers, New York (1990).
dc.relation.referencesen19. KuchlingH. Physik Nachschlageb¨ucher f¨ur Grundlagenf¨acher. VEB Fachbuchverlag, Leipzig (1973), (in German).
dc.relation.referencesen20. PatchettA. J., Meissen F., EngelW., BradshawA.M., ImbihlR. The anatomy of reaction diffusion fronts in the catalytic oxidation of carbon monoxide on platinum (110). Surf. Science. 454 (1), 341–346 (2000).
dc.relation.referencesen21. KostrobijP., Ryzha I. Two-dimensional mathematical model for carbon monoxide oxidation process on the platinum catalyst surface. Chem. Chem. Technol. 12 (4), 451–455 (2018).
dc.citation.issue1
dc.citation.spage129
dc.citation.epage136
dc.coverage.placenameЛьвів
dc.coverage.placenameLviv
dc.subject.udc519.876.5
dc.subject.udc66.011
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